Method and device for micro blasting with reusable blasting rods and electrically ignited cartridges

ABSTRACT

A apparatus, method and system to electrically ignite small explosive cartridges in boulders, bedrock, concrete and other materials so as to split the material into smaller pieces or to shape it. To ignite the propellant or other explosive charge electrically by melting at high temperature a bridge wire(s) or bridge ribbon(s) with electrical current which can be AC or DC. The bridge melts normally at over 2,000 degrees F. which will ignite the propellant or explosive. With sufficient voltage and amperage such as standard 110 volt AC wall current ionization takes place along the pathway of the melted bridge and a large electrical arc forms that ignites the propellant or explosive with even higher certainty as electrical arc temperatures are often over 5,000 degrees F. When the propellant or explosive is ignited at higher temperature there are known beneficial effects for increased blast power. The blast with this apparatus and method is tamped with a reusable blasting rod with an external groove for a blasting wire to fit into so electrical current can be supplied to the cartridge in the borehole. The blasting rod is normally attached to a counterweight or blasting head for better tamping and has a cradle on top for rocks or other heavy objects to be placed on top for even better tamping through the Newton Kinetic effect.

FIELD OF THE INVENTION

The present disclosure of this invention relates generally to the field of small scale rock, concrete and other material blasting with cartridges that have propellant or explosive charges and other methods of splitting rocks, concrete and bedrock.

DESCRIPTION OF THE RELATED ART

The present disclosure involves the novel features of the cartridges themselves, the blast containment system that consists of reusable blasting rods with an external groove for electrical wire and an inert electrical igniter combined with various systems, methods and apparatuses to prevent rapid expulsion of the rod from the blast hole on ignition and to do so in safe manner. In particular the current disclosure electrically melts thin metal or other conductive material wire or ribbon and then electrically arcs directly within the powder charge without dangerous pyrotechnic or explosives to ignite the powder charge. This provides an inert igniter that is not sensitive to shock or heat. The present disclosure provides reusable blasting heads and rods so as to speed blasting operation and reduce costs. The current disclosure eliminates many of the current limitations of the state of the art, including being able to fire multiple heads precisely at the same time as electricity is the initiating event, being easily expandable to firing many blast holes at the same time, being water resistant, being lightweight and having fast setup time compared to the state of the art.

Currently large scale blasting such as is done in open pit mines, requires the use of highly dangerous explosives that can dismember a person. There are small blasting systems that involve drilling a hole in rock and using explosive primers that explode on contact and are mechanically initiated primarily through firing pins traveling long distances through the center of blasting rods and striking the explosive primer. The explosive primer then explodes igniting additional propellant or explosives to generate the pressure to crack the rock. U.S. Pat. No. 7,069,862 describes one of these blasting inventions that uses a spring and lanyard firing method. CA 2599106 C is another patent of this type.

Another was to mechanically fire the long firing pin is by using air pressure generated from air tanks or air compressors which blows the firing pin like a blow dart until it hits the explosive primer in the cartridge underneath the hollow tamping rod as patent CA 2599106 C operates. The current state of the art has safety, versatility and reliability issues.

Lanyard triggered gravity firing systems do not allow blasting sideways or overhead. The long firing pins which can be 8 inches long are prone to sticking due to corrosion, clogging from blast dust and if the blasting rod is even slightly bent it will bind the firing pin inside the rod. They are primarily used for just one blasting head and getting multiple heads to go off at precisely the same time would be virtually impossible, as pulling multiple strings would be involved.

Air pressure fired firing pin systems require a heavy air compressor or some form of an air tank and air manifolds and air hoses and often require very high pressures, such as 120 psi to be effective in pushing the firing pins into the explosive primer. This is an issue as miners often need to back pack blasting systems into remote areas. For multiple head blasts some air pressure fired systems can accomplish such by using a large air tank with air manifolds and multiple air hoses to go to the various blasting heads. However, mechanical firing pins propelled by air pressure to multiple blasting heads will inherently be less precise timing-wise than an electrical firing system going to multiple heads at roughly the speed of light. The maximum number of blasting heads currently marketed to be used at once is three (that we the inventors of the current disclosure are aware of). The current disclosure allows for an almost unlimited number of blasting heads to be fired at the same time with great precision.

The inventors of the current disclosure have observed many reliability issues with air fired systems where firing pins stick in the blasting rods due to sticking from condensation in the firing pin path that causes corrosion. The current disclosure solves these problems and has several novel advantages for this field of blasting.

There are other small blasting systems. U.S. Pat. No. 4,669,783 A, process and apparatus for fragmenting rock and like material using explosion-free high pressure shock waves, uses a quite different method to crack the rock, as does U.S. Pat. No. 6,339,992 B1, small charge blasting apparatus including device for sealing pressurized fluids in holes. One method that does utilize electrical firing is U.S. Pat. No. 8,342,095 B2, self-stemming cartridge, which uses a different method of tamping and utilizes a three step method of igniting the propellant/explosive, the first wherein an electrical charge applied to the fuse that actuates the igniter that then detonates the accelerant according to that patent.

U.S. Pat. No. 3,040,660, electric initiator with exploding bridge wire, does have the precise timing as does the present disclosure, but its purpose and method are different. Its purpose it to directly detonate high explosives with the explosive force of the bridge explosion and the precise timing is for atomic bomb detonation by detonating explosives on different sides of the nuclear fissionable material as simultaneously as possible. The current disclosure is designed for igniting, not detonating, and is mostly for propellants and low explosives, not focused on high explosives, and is unlikely to be quite at precise timing wise that U.S. Pat. No. 3,040,660 achieves.

SUMMARY OF ADVANTAGES OF THE INVENTION

The present disclosure involves the novel features of the cartridges themselves and the blast containment system that consists of reusable blasting rods with various systems, methods and apparatuses to prevent rapid expulsion of the rod from the blast hole on ignition and to do so in a safe manner. In particular the current disclosure includes the electrical melting and electrical arcing of thin metal wire or ribbon directly within the propellant/explosive charge without dangerous pyrotechnic or explosives to ignite the charge. This provides an inert igniter that is not sensitive to shock or heat. After the electrical bridge melts, an electrical arc forms even with standard 110 AC wall current as the air is ionized and more conductive after heating, which aids ignition reliability and often improves the explosive power of propellants due to the higher initiation temperature. The present disclosure provides reusable blasting heads and rods so as to speed blasting operation and reduce costs. The current disclosure eliminates many of the current limitations of the state of the art, including being able to fire multiple heads precisely at the same time as electricity is the initiating event, being water resistant, being lightweight, having fast setup time and having a solid blasting rod with an external path for the blasting wire that can be easily cleaned if it clogs with blast dust. The invention also has the ability to increase blasting power by simply inserting extra cartridges into the hole before lowering the primary charge that attaches to a nipple at the end of the blasting head rod. When the primary cartridge is ignited it reliably ignites other cartridges in the same blast hole whether they are primary cartridges with igniters or booster cartridges which have no igniters. Booster cartridges have just propellant or explosives inside the case of the cartridge.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a drawing (with many sub-components) of the cartridge in the present invention;

FIG. 2 is a view of the end of the blasting rod to which the cartridge attaches in the present invention;

FIG. 3 is a view of the blasting rod installed into a drill hole after the pictured boulder has already been split by a blast of the present invention;

FIG. 4 is a electrical diagram of the trigger, wiring and blasting heads of the present invention;

FIG. 5 is a detail view of a blasting head, blast cord, blasting wire and cartridge of the present invention;

FIG. 6 is a detail view of the blasting head and the components that attach to the blasting head in the present invention; and

FIG. 7 is a detail view of the blasting head tether cord of the present invention.

SUMMARY OF THE INVENTION AND DETAILED DESCRIPTION OF THE DRAWINGS

The present disclosure provides an apparatus, system, and method with several embodiments that overcome the limitations of the prior art. The present disclosure accomplishes this by having an inert igniter that is ignited by electrical current. The preferred embodiment for the igniter is thin metal wire(s) or ribbon(s) FIG. 1, 15 connected between two conductors on the blasting wire 5 directly in the propellant or explosive material 10. The invention has a firing system that sends electricity which can be DC or AC with the preferred embodiment being DC current down the blasting cartridge wire which is a two conductor wire FIG. 1, 5 to the igniter bridge FIG. 1, 15 that connects those two wires with an inert thin metal wire(s) or ribbon(s). AC current works very well for the present disclosure, and has simplicity advantages in terms of using an unaltered standard source.

When the electrical current is applied by an electrical trigger FIG. 4, 40, which is part of the overall blasting system of this invention, the thin metal igniter bridge FIG. 1, 15 melts normally at over 2,000 degrees F. and also generates an electrical arc if there is sufficient voltage and amperage, that is similar to an arc welding arc, generating even more heat in addition to the molten metal. The preferred embodiment for the material for the thin metal bridge is stainless steel and the preferred embodiment is to have multiple strands for extra reliability although the invention is not limited to those embodiments and works well with other metals and works well with just one strand. This invention is not limited to using metal for the igniter bridge FIG. 1, 15; any material that is conductive and will generate sufficient heat and then melt, breaking the circuit and igniting the propellant/explosive can be used. Pyrotechnic materials can be added to the electrical bridge but the preferred embodiment is to not use them. This method and apparatus is reliable in igniting the propellant/explosive charge and is inert. The igniter bridge can be hammered or heated, just as long as it is significantly below its melting point, which is often over 2,000 degrees F. for stainless steel and many other appropriate materials, without catching fire or exploding, as it is inert. It is much safer that shotgun shell primers or pyrotechnic materials used by other igniter systems in terms of shock and heat resistance.

The invention's preferred embodiment is to use propellants instead of high explosives so it can be shipped and stored with less legal requirements and expenses than explosives. These cartridges can be triggered outside of a drill hole with little noise and danger compared to explosives and little force compared to the force generated when they are contained in drill holes with a blasting rod which will be described further in the current disclosure. With protective welders gloves and clothing and a face shield, a cartridge FIG. 5, 11 has been ignited on a heavily gloved hand without harming the person. Yet in a blast hole with containment the same cartridge can split a 3 foot diameter rock boulder into two or more pieces.

The cartridge in the preferred embodiment is a plastic tube such as the 0.375″ OD and 0.25″ ID one that is sealed on both ends as shown in FIG. 5, 11 and also shown in exploded detail in FIG. 1, so as to be water resistant. The invention is not restricted to that size. The cartridges FIG. 5, 11 can thus be used underwater unlike the known state of the art on the market in which blasting cartridges are often rolled paper. The blasting wire FIG. 1, 5 with the igniter bridge FIG. 1, 15 is positioned in the cartridge tube with the preferred embodiment being the igniter bridge is centered in the powder for the fastest complete ignition time of all the propellant/explosive.

In the preferred embodiment an additional plastic tube or tubes FIG. 1, 12 surround the blasting wire FIG. 1, 5 inside the main cartridge tube. This aids in centering the wire and provides additional containment of the high pressure gases that are generated on ignition. In the preferred embodiment a glue, molten plastic or other material FIG. 1, 17 that sticks to the inside of the main cartridge tube is then used to help seal the cartridge on the blasting wire side. To prevent the blasting wire from being pulled out of the cartridge the wire is knotted or otherwise deformed as seen in FIG. 1, between 17 and 12 so it takes a larger pulling force to pull the wire out of the cartridge. On the non-blasting wire side of the cartridge the propellant/explosive charge FIG. 1, 10 is contained in the cartridge by glue, molten plastic or other material FIG. 1, 16.

The blasting head apparatus FIG. 4, 20 consists of a blasting rod FIGS. 2 and 5, 24 which has a groove FIG. 5, 25 on the outside for the blasting wire to fit in for insertion into the blast hole FIG. 2, 30 and a blasting head FIG. 3, 26. The blasting rod FIG. 3, 24 connects to the blasting head FIG. 3, 26 by welding, bolting or other known methods of attachment and provides a counterweight to the high pressure force of the blast that will try and push the blasting rod FIG. 3, 24 out of the drill hole FIG. 3, 30 in the rock, concrete or other desired material to blast as in FIG. 3, 31 on ignition. In addition to the weight of the blasting head FIG. 3, 26 this invention uses a method to further contain the force and pressure of the blast by having blasting head ring FIG. 6, 56 made of rubber or similar material to cradle an additional weight which is often but not limited to a rock as shown in FIG. 3, 29. During a blast the force is transferred through the blasting head into the rock, or other object FIG. 3, 29 similar to the kinetic energy effect of bowling balls or ball bearings in that the blasting head FIG. 3, 26 stays quite stationary and the rock or other additional weight placed on top of it is what moves. This method has many advantages including it reduces the weight of carrying the blasting system into the field and it greatly slows down the rising of the blasting rod on ignition so the space under the rod stays smaller longer which translates into higher pressures and better splitting force for the blast. The blasting head ring FIG. 6, 56 is rubbery also to provide a cushion if the blasting head FIG. 3, 26 hits another object or a person for improved safety.

The electrical current is delivered to the blasting wire FIG. 1, 5 from its source whether that is standard wall current or a generator or a battery or other source through the blasting trigger FIG. 3, 40 which in the preferred embodiment converts AC current, if it is AC, to DC or leaves it as DC if it is DC, via a bridge rectifier or similar converter. In the preferred embodiment the converter is part of the blasting trigger apparatus FIG. 3, 40. Converting to DC is optional as the current disclosure works very well with standard AC current. The electrical current exiting from the blasting trigger is transmitted into the blasting extension cord FIG. 4, 42 to the blasting electrical distributor FIG. 4, 44 which then distributes the electrical current to one or more blasting head cord(s) FIG. 4, 46 and the preferred embodiment is to have more that one place to plug in blasting head cords into the distributor for redundancy. The preferred embodiment for blasting head cords FIG. 4, 46 is that they have a daisy chain feature on the connector that inserts into the blasting electrical distributor FIG. 4, 44, so that another blasting head cord can be plugged into the previous blasting head cord plugged into the electrical distributor FIG. 4, 44 with an electrical connection being made to the previous plug enabling even more concurrent blasts than the number of available plugs on the distributor. The blasting head plug shown in FIG. 6, 49 is just such a type of piggyback plug but on that end of the blasting head cord the holes for piggybacking are filled with the electrically connected push terminals FIG. 6, 31.

The current disclosure has a preferred embodiment of having push terminals FIG. 6, 31 electrically and mechanically attached to the blasting head plug FIG. 4, 49 on the blasting head cord FIG. 5, 46. The blasting head cord FIG. 5, 46 in the preferred embodiment attaches to the blasting head via the blasting head plug FIG. 6, 49 without electrical connection to the blasting head, the female holes in the blasting head are non-conductive, but to position it for the push terminals FIG. 6, 31 to be near the blasting wire FIG. 6, 5 for connection and to provide a firm anchor point that is non-electrical. The blasting head plug FIG. 6, 49 is protected from damage from rocks and other blows during blasting by the blasting head plug protector rod FIG. 6, 51. It is also protected from blast dust and flame by a blast hole shield FIG. 5 and FIG. 6, 52 which pivots out of the way for connecting the blasting wire and then pivots back protecting the blasting head plug before ignition.

A blasting head tether cord FIG. 7, 61 is attached to the blasting head anchor FIG. 3, 58 with cord attachment FIG. 7, 66 and to an anchor plate FIG. 7, 63 and has a tether cinch FIG. 7, 57. This is to prevent the blasting head from flying through the air or rolling down a hill. The anchor plate FIG. 7, 63 is held to another boulder or other object by a screw FIG. 7, 64, or attached in another fashion to an object expected to stay in place. For sideways or overhead blasting this invention has an optional heavier blasting head that does not require a movable object to be placed on top of it for increased containment of the cartridge blast. The preferred embodiment for the blasting head tether cord FIG. 7, 61 uses an elastic cord such as a bungee cord for the tether cord so as to provide tension for sideways or overhead blasts, yet stretches so as to allow the blasting head apparatus to exit the blasting drill hole during the blast.

OPERATION OF THE INVENTION

The following operation of the invention is just one of many ways to use it and the current disclosure is not limited to this one method of operation. A way to use the invention is to first disconnect the blasting extension cord FIG. 4, 42 from the trigger cord for safety then optionally attach a shorting device not shown, into the now open blasting extension cord plug FIG. 4, 42 so as to prevent radio waves or the like from entering the wires in the cord. Then disconnect the blasting extension cord FIG. 4, 42 at the other end from the blasting electrical distributor FIG. 4, 44. The blasting head cords FIG. 4, 46 in the preferred embodiment are twisted pair wires to prevent radio or similar waves from entering them. The next step is to connect, if it is not already, the blasting head cord(s) 46 at both ends. Then drill a hole in the boulder, concrete, bedrock or other medium the user desires to split/blast, of approximately 8 inches to 12 inches in depth.

The hole can be drilled much deeper and if water or other liquid is put into the borehole a column of liquid can be created beneath the primary and or booster cartridge(s), which do float, or can be taped together. This allows for the pressure of the blast to be exerted over a longer column than the cartridges, as liquids are incompressible. Potentially if the water only column under the cartridges is about as long as the cartridge(s) are, the blast tension on the material being split or blasted could potentially be doubled with the same amount of explosive charge. This method of drilling past the cartridge placement has an additional advantage of weakening the rock/material being blasted as it removes more of the material next to the explosive force. Drilling in rock and concrete with the current state of the art is common and inexpensive. The drill hole FIG. 3, 30 is drilled slightly larger than the blasting head rod so the rod can be fit easily into the hole later. After the drill hole FIG. 3, 30 is drilled it can be brushed or blown out by air if necessary.

The cartridge FIG. 5,11 can then be attached to the blasting head rod nipple FIG. 2, 28 by pressing it over the nipple as there is a cavity in the cartridge for attaching to the nipple and doing so with the blasting wire FIG. 6, 5 aligned to the blasting head rod groove FIG. 5, 25. This cartridge holding apparatus and method of this invention makes extracting the cartridge easy in case the user decides to not blast after inserting it. Then the far end of the blasting wire FIG. 6, 5 can be inserted into the push terminals FIG. 6, 31 to electrically connect the blasting wire to the blasting head cord plug FIG. 6, 49. The user can next place the blasting wire into the groove with the preferred embodiment being to do so on its edge with the groove being a tight fit for better gas pressure containment during the blast. This can be done with a finger or thumb even with gloves on. At this point the cartridge FIG. 5, 11 is still not contained, it is in the open air.

Before inserting the blasting head rod with the attached cartridge as shown in FIG. 3 an additional booster cartridge FIG. 3, 33 or more than one depending on regulations can be inserted into the blasting hole to increase the power. Booster cartridges are ignited by the primary cartridge's heat and/or pressure reliably, without any igniter in the booster cartridge. FIG. 3, 34 shows the place on the blasting hole where the cartridge FIG. 5, 11 would be before the blast and where a booster cartridge FIG. 3, 33 would be located. The next step is to place the blasting head rod FIG. 2 and FIG. 3, 24 down into the blast hole with an installed cartridge FIG. 5, 11. If it gets stuck before or after the blast the user can rotate it in the preferred embodiment either by twisting the head with their hands with their head for safety out of line with he head or apply a wrench to the built in welded nut that is seen attached to the blasting head anchor FIG. 3, 58. The blasting head rod FIG. 2, 24 has threads FIG. 2, 25 on it near the bottom in the preferred embodiment to generate outward thrust similar to how a screw does when turned. The blasting rod threads FIG. 2, 25 serve another purpose as gases attempting to escape between the blasting rod and blasting hole during the blast are very high velocity, even supersonic, and the threads aid containment by generating turbulence to slow down the exit of the gases.

After the blasting head rod FIG. 3, 24 and cartridge(s) are placed into the blasting hole the user should be careful to avoid being in line with it, if it were to ignite. However since the igniter FIG. 1, 15 is inert and significant amperage is required to ignite it, this should not be an issue. Unlike the current state of the art for small blasting, the current disclosure has no explosive or pyrotechnic material in the igniter, so it is not sensitive to pressure or heat as are explosive and pyrotechnic material igniters and thus is safer and much less likely to ignite accidentally. Due to the water resistant nature of the cartridge in this invention, water can be poured down the hole to submerge the cartridge(s) to increase containment and reduce noise.

If so desired the user can now put a rock, brick or other object FIG. 3, 29 on top of the blasting head FIG. 3, 26 with the preferred embodiment being to have a rubbery ring FIG. 6, 56 on top of it with a depression in the center so as to help hold a rock/other weight object to stay on top even if the drill hole is at a moderate angle. The user can at this point retrace his steps to a safe distance while reconnecting the blasting extension cord FIG. 4,42 at both ends and to connect the blasting trigger FIG. 4, 40 to an electrical power source if it is not already connected. Then, the user makes sure it is safe to blast and pushes the trigger which sends electricity to the cartridge FIG. 5, 11 which ignites and then blasts what the user had targeted to blast such as the split boulder in FIG. 3, 31. This operation can be done with one blasting head or many at the same time as the electricity can be distributed to many heads easily with this invention. The current disclosure can be used without the trigger simply by plugging a cord in to a power source, but the preferred embodiment is to use the described safety apparatuses and methods. The preferred embodiment uses specialized electrical connectors so standard electrical plugs can not be accidentally connected causing accidental ignition.

The setup time to do all the above operations except drilling is often less than three minutes. The time to drill a 10 mm hole, which is appropriate for a ⅜″ cartridge and ⅜″ blasting head rod, 10″ deep can be as little as one minute in volcanic rocks, less than one minute in concrete and can be over four minutes in hard to drill rocks, such as chert. Currently a SDS rotary hammer drill to drill that fast can be bought for less than $100, so the equipment to drill the necessary holes for this invention is inexpensive and drilling times are quite acceptable.

While a number of exemplary aspects and embodiments have been discussed above, those of skill in the art will recognize certain modifications, permutations and additions and subcombinations thereof. It is therefore intended that the following appended claims and claims hereinafter introduced are interpreted to include all such modifications, permutations, additions and subcombinations that are within their true spirit and scope. 

1. An apparatus and method for igniting propellants and low explosives comprised of a very thin inert metallic or non-metallic bridge wire(s) or bridge ribbon(s), with one example being but not limited to three 0.001″×0.003″ stainless steel ribbons, that melt at well over 2,000 degrees F. that allows for standard 110 volt AC electrical current from a standard wall source, a generator source or a inverter source, or any source and also DC current of similar voltage and amperage from any source to arc the gap as the air is ionized and more conductive after the heating caused by the melting inert bridge wire, thus being able to jump a much larger gap and producing a higher heat, often over 5,000 degrees F., than would be possible without the bridge wire(s) ribbon(s) first melting and thus igniting with greater certainty the propellant or low explosive charge that said bridge wire(s) or ribbon(s) is buried in and the higher initiation temperature of the arc can increase the explosive power of propellants and low explosives and the said bridge wire(s) or ribbon(s) can work with less than and more than the standard 110 voltage in AC or DC and has the precise timing benefits of exploding bridge wires (EBWs) in terms of igniting a plurality of charges simultaneously, although it does not generate detonation as EBWs do with high explosives and said bridge wire(s) or ribbon(s) are immune from normal static electricity being able to cause accidental ignition.
 2. An apparatus and method as described in (1) that allows for a very wide range of electrical sources to ignite propellants and low explosives by another method, whereby the bridge wire(s) or ribbon(s) melts and thus ignites the propellant or low explosive by the heat of the melting which is normally over 2,000 degrees F., which can be achieved with as small of an electrical current as two 1.5 volt AA batteries in series producing 3 volts and depending on amperage this melting without an large arc being produced after the said bridge melts can take place up to and over 24 volts and will still reliably ignite propellants and low explosives.
 3. A method of igniting propellants and explosives faster by having the igniter/detonator placed in the center of the explosive charge as this is twice as fast for total combustion of the explosive charge than igniting/detonating the charge from one end which produces more energy and pressure faster especially in blasting systems where the tamping allows some of the expanding gases to escape through gaps or by pushing the tamping material out.
 4. An apparatus and method consisting of an explosive cartridge which can be water resistant that has a tube with an explosive/propellant charge in it that has end caps and is electrically fired by a two conductor wire connected to an internal inert electrical igniter on one end of the wire as described in claim (1) and to an electrical source on the other end and that other end can be outside the borehole in a rock or other materiel to be split or blasted with a reusable tamping rod or non-reusable tamping material to provide containment of the blast.
 5. An apparatus and method that provides a reusable tamping of an explosive cartridge or charge consisting of a blasting rod attached to a blasting head or counterweight and having an external groove in the blasting rod for a small electrical wire to fit into that is used to fire the explosive cartridge contained by this reusable tamping apparatus in the borehole with minimal gas blow-by past the blasting rod.
 6. An apparatus and method as described in (5) that also has a nipple on the blasting rod end that the blasting cartridge fits snugly over to create an assembly for easy placement of the cartridge and blasting rod into the borehole and extraction of said cartridge and blasting rod if the user so desires.
 7. An apparatus and method as described in (5) that also has a cradle such as a rubber ring on top of the blasting head so that a rock, brick or other object can be placed on top and remain on the top of the blasting head even if the blasting head is at a moderate angle so that not only is the weight on the rod higher for better tamping, the Newton Kinetic effect can also be utilized when the blast takes place which transfers the energy to the rock or other object on top which flies upward thus allowing the blasting head to remain in place longer which reduces the below the blasting rod space in the borehole which increases the pressure generated from the same size cartridge and this cradle can be made of a soft or rubbery material to aid user safety.
 8. An apparatus and method as described in (5) that also permits an electrical source (blast cord) to be attached to said blasting head and for the electricity from that blast cord to be transferred to the blasting wire that goes into the blasting cartridge by a quick connect method and apparatus such as the push terminals described in the specification and said blasting head can have a blasting head plug protector rod to protect the electrical connection from being damaged by dropping or rock strikes.
 9. A multiple blasting head electrical igniter apparatus and method that utilizes a electrical distributor and or electrical connectors on the blast cords that can be piggybacked so that a plurality of blasting heads can be fired simultaneously with great timing precision as the igniter method in claim (1) allows, so that intersecting shock wave planes can be generated in the rock or other materials being blasted or split and the power of all the blasts is exerted together for improved splitting ability.
 10. A blasting system and method consisting of an electrical trigger of any type including a switch, connected to a electrical power source, or any other method that when triggered sends electrical current which can be AC or DC down an extension cord so as to provide for the user to be a safe distance from the blast and that extension cord connects to a distributor for a plurality of blasting heads/boreholes or to a single blasting head through blast cords that connect to blasting wires attached to blasting cartridges tamped with reusable blasting rods and heads and those said blasting wires fit into an external groove in the blasting rod to protect the blasting wires and increase containment and those blasting wires connect to an inert igniter in the blasting cartridge which is filled with an explosive material or propellant that ignites when the electrical current arrives which generates significant pressure, as it is contained by the blasting rod in the borehole, which normally leads to the boulder or other material being split into two or more pieces.
 11. A method of increasing the power of the blast created by the apparatus described in claim (4) by pouring water or other liquid into the borehole as this decreases the air space in the space below the blasting rod and increases the tamping effect as liquids are non-compressible and are harder to push past the blasting rod borehole gap than air is, and this is possible as the blasting cartridge apparatus in claim (4) is easily made in a water resistant manner.
 12. A method and apparatus to allow upside down blasting by having a elastic cord or clinched rope or similar attached on one end to the blasting head/blasting rod as described in claim (5) and anchored on the other end to an anchor bolt, tree or other object to anchor to so as to prevent the blasting head/blasting rod from falling out of the borehole due to gravity.
 13. A method and apparatus to tether the blasting head/blasting rod so as to prevent it from flying dangerously out of the borehole or being lost when next to a river or a cliff or other hazard consisting of an elastic bungee cord, rope or cable that is attached on one end to anchor bolt or similar stationary object and on the other end to the blasting head/blasting rod.
 14. A method and apparatus to increase the blasting power of this invention by the addition of booster cartridges that are similar in diameter, container type and propellant or explosive material to the cartridge described in claim (4) that can be placed in the borehole before the primary cartridge as described in claim (4) is inserted into the borehole, with said booster cartridge not requiring an igniter or blasting wire as said booster cartridge is reliably ignited by the ignition of the primary, cartridge described in claim (4) or similar blasting device, even if it is submerged underwater and the said booster cartridge is not limited numerically to one, as two, three or more booster cartridges may be added and all will ignite when the primary cartridges as described in claim (4) especially if the blast wire is cut off first.
 15. A method and apparatus consisting of the blasting rod in claim (5) also having threads in the rod so if the rod get stuck in the rock/concrete it can be screwed out by hand or by wrench and those same threads provide additional turbulence so as to slow down escaping gases from the borehole for better containment during the blast.
 16. A method and apparatus consisting of the blasting rod in claim (5) also having a blast hole shield to protect the electrical components from dust and damage and this blast hole shield can be so made so as to pivot on the blast rod to get it out of the way then pivot it to protect the electrical components before the blast.
 17. A method of increasing the blasting power of this invention by drilling the borehole deeper than required to fit the cartridge(s) and blasting rod and filling the void underneath the cartridge(s) with water or other liquid so a column of liquid is created beneath the primary and or booster cartridges, which do float, or can be taped together and by doing so potentially the same pressure of the blast can be exerted over a longer column than the cartridges, as liquids are incompressible, and potentially the blast tension on the material being split or blasted could be doubled with the same amount of explosive charge if the total below blasting rod borehole length is doubled and this increase is variable depending on the amount a additional water column and this method of drilling past the cartridge placement has an additional advantage of weakening the rock/material being blasted as it removes more of the material next to the explosive force. 